A method for controlling longitudinal dynamics in a motor vehicle during an autonomous driving operation, where the presence of a front vehicle traveling ahead of the vehicle is ascertained with the aid of a surround sensor system; ascertaining at least one longitudinal dynamics variable of the front vehicle, which describes the longitudinal vehicle dynamics of the front vehicle, with the aid of the surround sensor system; and ascertaining at least one variable, which is used in a brake control system of the motor vehicle, as a function of the longitudinal dynamics variable of the front vehicle.
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1. A method for controlling a motor vehicle, the method comprising:
ascertaining a presence of a front vehicle traveling ahead of the motor vehicle with the aid of a surround sensor system;
ascertaining information regarding a deceleration of the front vehicle;
based on the ascertained information regarding the deceleration of the front vehicle ascertaining an initial deceleration value of the motor vehicle; and
in response to a setting of a target braking value of the motor vehicle, which requires an increase of braking torque of the motor vehicle, and in accordance with the ascertained initial deceleration value:
initiating the increase of the braking torque to increase a deceleration of the motor vehicle towards the ascertained initial deceleration value; and
during the increase of the braking torque that has been initiated, in response to the deceleration of the motor vehicle reaching the ascertained initial deceleration value prior to the target braking value being reached, lowering a rate of the building up of the braking torque so that the increase of the brake torque that had been initiated continues to thereby increase the deceleration of the motor vehicle beyond the ascertained initial deceleration value, but at the lower rate.
11. A device for controlling a motor vehicle, the device comprising:
a controller configured for performing the following:
ascertaining a presence of a front vehicle traveling ahead of the motor vehicle with the aid of a surround sensor system;
ascertaining information regarding a deceleration of the front vehicle;
based on the ascertained information regarding the deceleration of the front vehicle ascertaining an initial deceleration value of the motor vehicle; and
in response to a setting of a target braking value of the motor vehicle, which requires an increase of braking torque of the motor vehicle, and in accordance with the ascertained initial deceleration value:
initiating the increase of the braking torque to increase a deceleration of the motor vehicle towards the ascertained initial deceleration value; and
during the increase of the braking torque that has been initiated, in response to the deceleration of the motor vehicle reaching the ascertained deceleration value prior to the target braking value being reached, lowering a rate of the building up of the braking torque so that the increase of the brake torque that had been initiated continues to thereby increase the deceleration of the motor vehicle beyond the ascertained initial deceleration value, but at the lower rate.
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The present application is the national stage of International Pat. App. No. PCT/EP2017/057748 filed Mar. 31, 2017, and claims priority under 35 U.S.C. § 119 to DE 10 2016 209 733.4, filed in Germany on Jun. 2, 2016, the content of each of which are incorporated herein by reference in their entireties.
The present invention relates to a method and device for controlling longitudinal dynamics in a motor vehicle during an autonomous driving operation.
Patent document DE 10 2014 209 015 A1 discusses a method of controlling distance for a vehicle, the vehicle including an image acquisition device and a surround sensor system, the surround sensor system supplying an environmental signal, which represents a positional information item and/or a speed information item for at least one vehicle traveling ahead, the method including a step of inputting an image information item of the image acquisition device, a step of ascertaining at least one environmental information item, using the image information item, as well as a step of defining a distance control signal, using the environmental signal, and using the environmental information item, in order to implement distance control for the vehicle.
The present invention relates to a method for controlling longitudinal dynamics in a motor vehicle during an autonomous driving operation, where the presence of a front vehicle traveling ahead of the vehicle is ascertained with the aid of a surround sensor system;
at least one longitudinal dynamics variable of the front vehicle, which describes the longitudinal vehicle dynamics of the front vehicle, is ascertained with the aid of the surround sensor system; and at least one variable, which is used in a brake control system of the motor vehicle, is ascertained as a function of the longitudinal dynamics variable of the front vehicle.
By evaluating the operating dynamics of a vehicle traveling ahead, a brake control system is provided data for optimizing its braking actions. These additional data are important, in particular, if the brake control system is a secondary system, which is only used in response to a malfunction or defect of the primary system and its sensor signals and must ensure at least reliable emergency braking.
One advantageous refinement of the present invention is characterized in that the longitudinal dynamics variable of the front vehicle is the longitudinal deceleration of the front vehicle. Thus, this variable is particularly important, since it relates to the longitudinal dynamics of the vehicle crucial to braking actions.
One advantageous refinement of the present invention is characterized in that the at least one variable used in the brake control system of the motor vehicle is a limiting value of a longitudinal deceleration for the longitudinal deceleration of the motor vehicle achievable without locking the wheels; and that with the aid of the brake control system, an intervention in the longitudinal dynamics of the motor vehicle, independent of the driver, is carried out in such a manner, that the limiting value of the longitudinal deceleration is not exceeded. This refinement is based on the assumption that the motor vehicle may be decelerated at least just as sharply as a vehicle traveling ahead. In this manner, the execution of safe emergency braking is rendered possible.
One advantageous refinement of the present invention is characterized in that a braking torque acting on the wheels of the motor vehicle is built up at a first rate of increase, until the deceleration of the motor vehicle reaches the ascertained limiting longitudinal deceleration value; and that the braking torque is subsequently built up further at a second rate of increase, the second rate of increase being less than the first rate of increase. Without knowledge of the roadway coefficient of friction, a deceleration stronger than that of the front vehicle is associated with an increased risk of locking wheels. Therefore, upon reaching the limiting longitudinal deceleration value, only a slower build-up of braking force should take place.
One advantageous refinement of the present invention is characterized in that the action carried out by the brake control system, independently of the driver, is braking resulting in a dead stop of the vehicle. Consequently, in the case of a vehicle traveling in an autonomous or automated manner, the driver gains time to assume control over the vehicle.
One advantageous refinement of the present invention is characterized in that the brake control system of the motor vehicle is a secondary brake system, which is provided for emergency operation and is activated if a brake control system provided for the normal operation of the motor vehicle malfunctions.
One advantageous refinement of the present invention is characterized in that the secondary brake control system is a one-channel system. Consequently, the most important functionality is already ensured at a low cost.
One advantageous refinement of the present invention is characterized in that the surround sensor system is a video or radar sensor system. Such sensor systems are already prevalent in a number of modern vehicles.
One advantageous refinement of the present invention is characterized in that the surround sensor system is a sensor system, which receives information wirelessly from the vehicle traveling ahead, about its current vehicle deceleration or its current position. In this context, the vehicle position may be ascertained, in particular, using a GPS system. In this case, the GPS position of the vehicle traveling ahead may be used in the determination of its vehicle deceleration. In this instance, the communication with the vehicle traveling ahead may take the form of, in particular, car-2-car communication, but may also run over a central computer.
One advantageous refinement of the present invention is characterized in that the surround sensor system is a sensor system for determining the temporal change in the distance to the vehicle traveling ahead.
One advantageous refinement of the present invention is characterized in that the at least one variable used in the brake control system of the motor vehicle is a minimum value of the coefficient of friction of the roadway section traveled on by the front vehicle at the time of its determination.
In addition, the present invention includes a device, which contains devices that are configured to implement the method of the present invention. In this context, it is, in particular, a control unit, in which program code for executing the method of the present invention is stored.
In the area of automated, highly automated and partially automated driving of a motor vehicle, during normal operation, vehicle stabilization may be implemented by a device for active and passive brake pressure modulation at individual wheels, such as a vehicle dynamics control system, together with the corresponding actuators. This system provided for the normal case is referred to as the primary actuator system.
In the case of a malfunction of the primary actuator system, it is necessary for a secondary stabilizing actuator system or secondary actuator system to be available, which allows at least longitudinal stabilization of the motor vehicle. In this context, the following requirements are made of the secondary actuator system:
compliance with the order of locking must be ensured; that is, the rear axle wheels may only lock, if the wheels of the front axle are already locked;
the locking period of wheels may not exceed a predetermined temporal period, in order to ensure the ability of the motor vehicle to be steered; and
there must be an option of building up pressure actively and/or independently of the driver, in order to decelerate the vehicle in an automated manner.
During vehicle operation with a functional primary actuator system, information about the coefficient of friction of the road surface is available in some driving situations. In these driving situations, the coefficient of friction is ascertained from wheel speed data and further sensor information, which are associated with the primary actuator system.
For safety reasons, it is recommended that the sensor data of the primary actuator system not be used for the secondary actuator system, for in the event of a malfunction of the primary actuator system, its sensor data may be missing or erroneous. However, in the event of a malfunction of the primary actuator system and a hand-over to the secondary actuator system, this results initially in no ascertained coefficient of friction of the road surface being available.
In this connection, however, there is a limitation: Since the secondary actuator system must ensure at least longitudinal stabilization of the vehicle, the output signal of a longitudinal acceleration sensor not integrated in the primary actuator system must be available, for example, to the secondary actuator system. To that end, e.g., the secondary actuator system may access the longitudinal acceleration sensor used in the scope of an air bag control system, or a longitudinal acceleration sensor, which is shared with the primary actuator system, but whose signal processing does not take place in the primary actuator system, which means that this sensor is even available in the case of their failure. Alternatively, it is also possible to use information of wheel speed sensing elements in the secondary actuator system, if the signal acquisition and evaluation of the wheel speed sensing elements is not integrated in the primary actuator system, that is, if reliable wheel speed information is available even in the case of a malfunction of the primary actuating system.
In addition to the missing coefficient of friction, the variables describing the wheel states, such as the wheel speeds, are also not available in the case of a hand-over to the secondary actuator system. However, with the aid of a surround sensor system, it is possible to estimate a minimum value of a vehicle deceleration capable of being generated by braking actions of the secondary actuator system, without having to use current wheel speeds.
Using the longitudinal deceleration of a vehicle traveling ahead, which is ascertained with the aid of a surround sensor system, a minimum value or limiting value of the attainable deceleration of the ego vehicle may be estimated, and the build-up of brake pressure and the increase in vehicle deceleration by the secondary actuator system may occur as a function of that. In particular, the braking force may be increased very rapidly by the secondary actuator system, until the ascertained minimum value of the deceleration is reached. A further advantage of this is that due to the rapid, active increase in deceleration, the distance to the vehicle traveling ahead is decreased as little as possible.
In
This is represented with the aid of curve 101. However, if a vehicle traveling ahead is detected, which exhibits a high vehicle deceleration, then it may be concluded that the ego vehicle may also be decelerated sharply. Thus, a rapid build-up of brake pressure may take place in accordance with curve 102.
In
In
Input and output variables of the present invention are represented illustratively in
The basic operating sequence of the method according to the present invention is represented in
Schmidt, Thomas, Diekmann, Christoph, Strehle, Alfred
Patent | Priority | Assignee | Title |
Patent | Priority | Assignee | Title |
5382086, | May 03 1994 | Kelsey-Hayes Company | Vehicular antilock brake system incorporating improved adaptive control feature |
8538674, | Jan 04 2008 | ZF CV SYSTEMS EUROPE BV | Vehicle collision avoidance apparatus and method |
20080189040, | |||
20120022760, | |||
20130116909, | |||
20140032049, | |||
20150210280, | |||
20160114779, | |||
20170158225, | |||
CN103079917, | |||
DE102006060905, | |||
DE102011116112, | |||
DE102012203182, | |||
DE102013007857, | |||
DE102014209015, | |||
EP1344672, | |||
JP2012035818, | |||
JP2012038258, | |||
JP5330412, | |||
JP769201, | |||
WO2012020297, |
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